def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): if kwargs is None: kwargs = OrderedDict() pm_key = cls._child_xml_ns_key.get('ProcessingModules', ns_key) kwargs['ProcessingModules'] = _find_children(node, 'ProcessingModule', xml_ns, pm_key) return super(ProductProcessingType, cls).from_node(node, xml_ns, ns_key=ns_key, kwargs=kwargs)
def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): if kwargs is None: kwargs = OrderedDict() gkey = cls._child_xml_ns_key.get('GeoInfos', ns_key) kwargs['GeoInfos'] = _find_children(node, 'GeoInfo', xml_ns, gkey) return super(GeoDataType, cls).from_node(node, xml_ns, ns_key=ns_key, kwargs=kwargs)
def _deserialize_multipolygon(cls, node, xml_ns, tag='MultiPolygon'): mp_node = _find_first_child(node, tag, xml_ns, 'sfa') if mp_node is None: return None p_nodes = _find_children(mp_node, 'Element', xml_ns, 'sfa') return [ cls._extract_polygon(p_node, xml_ns, tag='Ring') for p_node in p_nodes ]
def _deserialize_multilinestring(cls, node, xml_ns, tag='MultiLineString'): mls_node = _find_first_child(node, tag, xml_ns, 'sfa') if mls_node is None: return None ls_nodes = _find_children(mls_node, 'Element', xml_ns, 'sfa') return [ cls._extract_line(ls_node, xml_ns, tag='Vertex') for ls_node in ls_nodes ]
def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): if kwargs is None: kwargs = OrderedDict() kwargs['SubRegions'] = _find_children(node, 'SubRegion', xml_ns, ns_key) return super(GeographicCoverageType, cls).from_node(node, xml_ns, ns_key=ns_key, kwargs=kwargs)
def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): if kwargs is None: kwargs = OrderedDict() # parse the ModuleName mn_key = cls._child_xml_ns_key.get('ModuleName', ns_key) mn_node = _find_first_child(node, 'ModuleName', xml_ns, mn_key) kwargs['ModuleName'] = _get_node_value(mn_node) kwargs['name'] = mn_node.attrib.get('name', None) # parse the ProcessingModule children pm_key = cls._child_xml_ns_key.get('ProcessingModules', ns_key) kwargs['ProcessingModules'] = _find_children(node, 'ProcessingModule', xml_ns, pm_key) return super(ProcessingModuleType, cls).from_node(node, xml_ns, ns_key=ns_key, kwargs=kwargs)
def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): dim1 = int_func(node.attrib['size']) dim2 = int_func(node.attrib['numLuts']) arr = numpy.zeros((dim1, dim2), dtype=numpy.uint16) lut_key = cls._child_xml_ns_key.get('LUTValues', ns_key) lut_nodes = _find_children(node, 'LUTValues', xml_ns, lut_key) for i, lut_node in enumerate(lut_nodes): arr[:, i] = [str(el) for el in _get_node_value(lut_node)] if numpy.max(arr) < 256: arr = numpy.cast[numpy.uint8](arr) return cls(LUTValues=arr)
def from_node(cls, node, xml_ns, ns_key=None, kwargs=None): numPhasings = int_func(node.attrib['numPhasings']) numPoints = int_func(node.attrib['numPoints']) coefs = numpy.zeros((numPhasings + 1, numPoints + 1), dtype=numpy.float64) ckey = cls._child_xml_ns_key.get('Coefs', ns_key) coef_nodes = _find_children(node, 'Coef', xml_ns, ckey) for cnode in coef_nodes: ind1 = int_func(cnode.attrib['phasing']) ind2 = int_func(cnode.attrib['point']) val = float(_get_node_value(cnode)) coefs[ind1, ind2] = val return cls(Coefs=coefs)
def _extract_polygon(cls, node, xml_ns, tag='Ring'): v_nodes = _find_children(node, tag, xml_ns, 'sfa') return [cls._extract_line(v_node, xml_ns, tag='Vertex') for v_node in v_nodes]